JP2008215609A - Quick connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a quick connector device enabling incorporation of a system sensing element into a connector body. <P>SOLUTION: This quick connector device has an accessory housing. The accessory housing contains a system sensing device such as an absolute pressure sensor or a pressure differential sensor in the state of liquid-tight with the housing. A receptacle portion is arranged to connect the sensor to a measuring instrumentation. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

Detailed Description of the Invention
The present invention relates to a fluid system quick connector for connecting a rigid tube to a flexible hose or other system component. More particularly, the present invention relates to a quick connector that includes a mechanism for sensing conditions in the system.

  Quick connectors are commonly used to provide a permanent but separable connection between a rigid tube and a flexible hose or other component. Such connection parts are disclosed in U.S. Pat. Nos. 5,161,832, 5,324,082, 5,423,577, 5,586,792, 5,626, 371, 5,628,531, 5,863,077, 6,846,021, and US Patent Publication No. 2005/0218650, each of these subjects. Is hereby incorporated by reference.

  Such quick connectors are widely applied but are particularly useful in vehicle fuel systems. Many of these connectors are used in liquid and / or vapor lines that contain modern automobile fuel systems.

  Today's evolution of engine operating diagnostics and control has shown the need to monitor operating conditions within the fuel system. In order to provide the necessary inputs for diagnostic or control functions, parameters such as fuel pressure or vapor pressure, vacuum, temperature, etc. must be sensed. The introduction of separate sensing elements has increased the number of components in a given system, as well as the number of locations that can be connections or leakage paths in the system. Alternatively, the addition of sensing elements to components such as fuel tank flanges has complicated design requirements and increased costs.

  The present invention provides a quick connector device that allows a system sensing element to be incorporated into a connector body. The connector body includes an integrally formed housing that defines a cavity or chamber having a removable cover for mounting various mechanisms, particularly a sensing mechanism. Within the scope of the present invention, the housing cavity can accommodate a wide variety of devices that may or may not be sensing mechanisms.

  The connector body defines a portion of the fluid path within the system. A path within the body provides fluid communication from the fluid system to the chamber.

  In the disclosed embodiment, a sensor in a housing integral with the connector body measures the value of the parameter being sensed and provides a signal indicative of that value. A receptacle receives an electrical plug that connects the sensor to a signal receiving and processing circuit.

[Embodiment]
Referring to FIGS. 1-5, a connector body of a quick connector coupling illustrating the present invention is shown. To illustrate the principles of the present invention, a connector body such as that disclosed in US Pat. No. 5,586,792 is shown. The contents of Patent No. 5,586,792 are incorporated herein by reference.

  The disclosure of US Pat. No. 5,586,792 describes a connector and fluid system components including a rigid tube and a flexible hose. In the following description, additions and modifications embodying the present invention are described in the quick connector body of Japanese Patent No. 5,586,792. However, the present invention is suitable for incorporation in any of the quick connectors specified above and in many other quick connector configurations known in the art.

  FIG. 1 shows a connector body 50 embodying the present invention. This is a substantially cylindrical elongated structure molded from a polymeric material such as nylon 12. This includes a wall 54 that defines a through-hole 56 that extends from a large diameter male member receiving end 58 to a barbed stem or hose connection end 60. The barbs cooperate in a known manner with the attached flexible hose to removably hold the flexible hose at the end 60.

  The illustrated stem end is suitable for attaching a flexible hose to the connector body 50. Many other end configurations are useful depending on the components used in the fluid system. For example, the end 60 may or may not be configured to use an O-ring seal between the end 60 and the attached line when secured to an inflexible or rigid line. It can also be configured. The connection can be fixed in various ways by crimping, magnaforming, or the like.

  By changing the diameter of the inner hole 56, the hole is divided into a fluid passage portion 110, a tube end receptacle portion 101, and a seal housing portion 90. The fluid passage portion 110 is in communication with an attached hose. Tube end receptacle portion 101 positions the end of the tube to be inserted. The seal housing portion 90 houses one or more O-ring seals and provides a fluid tight relationship with the inserted rigid tube.

  The body further defines a retainer housing section 70 adjacent to the male member receiving end 58. This includes an outer annular rim 72 and an inner annular rim 74 connected by a support member. A generally “U” shaped retainer 150 is located between the rims 72 and 74 which captures the tube upset so as not to dislodge and removably retains the male member within the connector body. As such, it cooperates with the male member in a known manner.

  In accordance with the present invention, the connector body 50 is provided with an accessory housing generally designated 170 which is integrally formed with the connector body 50. This includes an accessory cavity defining portion 172 and a receptacle portion 174. This is arranged substantially across the longitudinal axis of the through-hole 56 defined by the wall 54 of the body 50. However, the housing 170 can be oriented in any desired relationship to the length of the hole 56.

  The cavity defining portion 172 defines an accessory chamber 178 that houses a sensor or other device 292, described in more detail below. The cavity defining portion includes a lower wall 180 that extends partially within the same extent as the wall 54 of the connector body 50 as best seen in FIGS. The lower wall 180 includes a hole or passage 182 that communicates with the through hole 56. Thus, chamber 178 is in fluid communication with the fluid in the system including the quick connector coupling.

  A side wall 184 extends from the lower wall 180 in a direction away from the connector body 50 and defines an inlet having a peripheral rim 186.

  The receptacle portion 174 of the housing 170 includes a wall 190 that extends from one of the side walls 184 of the cavity defining portion 172 of the housing 170. The wall 190 defines a hollow plug storage chamber 192.

  A conductive prong or blade 194 is embedded in sidewall 184 in a fluid tight relationship and extends into chamber 178. The ends of the prongs 194 are exposed in the chamber 178 and include contacts that contact the circuitry of the sensor or other device 292.

  A lug 195 is provided outside the wall 190. This is configured to cooperate with an insertable plug (not shown) associated with the sensor monitoring device and the data processing device. The lug 195 detachably holds the plug in the hollow plug storage chamber 192. Appropriate contacts in the plug contact the prong 194 to complete the circuit to the device 292.

  A cover 196 is removably positioned on the rim 186. Cover 196 is connected to rim 186 in a fluid tight relationship. Cover 196 is removable for mounting device 292 in chamber 178 of housing 170.

  As best seen in FIG. 4, the cover 196 includes a port 197 that communicates the ambient atmosphere with the interior of the cavity or chamber 178. The port 197 is provided under the protective cap 198. This port or passage provides access to a reference source of the ambient atmosphere. The sensor 292 can provide a comparison signal based on the difference between the condition sensed in the fluid system and the corresponding parameter in the ambient atmosphere. The port 197 is isolated from the port or passage 182 by a device 292 disposed in the cavity 178 in fluid tight relation with the sidewall 184 so that the fluid tightness of the fluid system in the through hole 56 of the body 50 is achieved. Keep.

  A device 292 such as a strain gauge schematically shown in FIG. 12 can be inserted into the accessory chamber 178 of the accessory housing 170 of the embodiment of FIGS. This is placed in a cavity or chamber 178. To ensure fluid tight integrity of the fluid system incorporating the quick connector, the device 292 is sealed in a leaktight relationship to the sidewall 184 of the chamber 128 with a suitable sealant or potting material 291. Thus, there is no path between the port or passage 182 that communicates with the fluid system in the connector through-hole 56 and the port 197 of the cover 196 that is exposed to the atmosphere.

  The potting material 291 best seen in FIGS. 4 and 5 can be an epoxy, such as a cured liquid polysulfide, that provides superior insulation, sealing, reinforcement, and corrosion protection for the electrical connectors in the chamber 178. This is also resistant to hydrocarbon fuels. This is a pourable material that flows around the sensor 292 and the connector. This is also suitable for forming a seal connection between the cover 196 and the rim 186 of the sidewall 184 to ensure fluid tight integrity of the chamber 178.

  Referring to FIG. 12, a strain gauge pressure sensor is shown in place for sensing pressure in the fluid passage or hole 56 of the connector body 50. This includes a diaphragm 293 that receives fluid pressure in the passage 182 of the lower wall 180 and a metal foil 294 adjacent to the diaphragm 293. The foil senses distortion caused by the deflection of the diaphragm 293. A lead 295 is connected to a contact 191 that contacts the prong 194 to transfer an electrical signal to a meter (not shown), which converts the sensed signal into a pressure reading.

  Note that sensor 292 is coupled to accessory cavity or sidewall 184 of chamber 178 so that cover 196 need not be utilized for all applications. Sensing device 292 may include a lead 295 extending from the top of the device and exiting chamber 178 through an opening defined by rim 186.

  Device 292 can be any sensor suitable for performing a sensing function. This may be a temperature sensing transducer, a pressure or vacuum sensing transducer, or a thermistor that senses both temperature and pressure. The sensor can, for example, monitor the oxygen content or hydrocarbon content of the vapor in the fluid system.

  A quick connector including a main body having an accessory housing including an accessory chamber such as the chamber 178 is not limited to a sensor that recognizes and reports a system state, and can be used in any system device. Such system devices include leak detection devices, steam shut-off devices, variable orifice or flow control devices, steam purge devices, flow diverters, pulse dampeners, regulators, drains, manual shut-off devices, bleed off ports, and the like.

  With reference to FIGS. 6-11, the connector main body which shows this invention is shown. The connector body includes two portions positioned at 90 degrees relative to each other as shown in US Pat. Nos. 5,423,577 or 5,628,531, the disclosure of which is Which is incorporated herein by reference. The fluid system components including the rigid tube and flexible hose connected by the illustrated connector body are configured as described above and are known in the art.

  6 and 7 show a connector body 250 embodying the present invention. This is a substantially cylindrical elongated structure molded from a polymeric material such as nylon 12. This includes a wall 254 that defines a through hole 256 that extends from a large diameter male member receiving end 258 to a barbed stem or hose connection end 260. The barbs cooperate in a known manner with the attached flexible hose to removably hold the flexible hose at the end 260.

  The stem end shown is suitable for attaching the flexible hose to the body 250 of the connector. Many other end configurations are useful depending on the components used in the fluid system. For example, the end 260 may or may not be configured to use an O-ring seal between the end 260 and the attached line when secured to an inflexible or rigid line. It can also be configured. The connection can be fixed in various ways by crimping, magnaforming, or the like.

  The main difference between this embodiment and the embodiment of FIGS. 1-5 is that the connector body 250 has an “elbow” shape. That is, the male member receiving end 258 and the stem portion 260 are disposed at 90 degrees relative to each other, and the through hole 256 defines a fluid path including a 90 ° bend. This shaped quick connector is widely applied in places where space is limited, and can position rigid tubes and flexible hose paths at an angle to each other. It should be understood that this angle is not limited to 90 °. Any suitable angular relationship may be used between the male member receiving end 258 and the stem end or hose connector end 260.

  By changing the diameter of the inner hole 256, the hole is divided into a fluid passage portion 310, a tube end receptacle portion 301, and a seal storage portion 290. The fluid passage portion 310 is in communication with an attached hose. Tube end receptacle portion 301 positions the end of the inserted tube. The seal storage portion 290 houses one or more O-ring seals and provides a fluid tight relationship with the inserted rigid tube.

  The body further defines a retainer housing section 270 adjacent to the male member receiving end 258. This includes an outer annular rim 272 and an inner annular rim 274 connected by a support member. A generally “U” shaped retainer 350 is located between the rims 272 and 274 so as to capture the expanded diameter portion of the tube without detachment and releasably retain the male member within the connector body. Cooperate with male members in a known manner.

  In accordance with the present invention, the connector body 250 is provided with an accessory housing generally indicated at 370 that is integrally formed with the connector body 250. This includes an accessory cavity defining portion 372 and a receptacle portion 374. This is disposed at the hose connection end 260 substantially parallel to the longitudinal axis of the through hole 256 defined by the wall 254 of the body 250. However, the housing 370 can be oriented in any desired relationship to the length of the hole 256.

  The cavity defining portion 372 defines an accessory chamber 378 that houses a sensor or other device as described in connection with the embodiment of FIGS. The cavity defining portion includes a lower wall 380 that extends partially within the same extent as the wall 254 of the connector body 250. Lower wall 380 includes a hole or passage 382 that communicates with through hole 256. Thus, the sensor chamber 378 is in fluid communication with the fluid in the system including the quick connector coupling.

  A sidewall 384 extends from the lower wall 380 in a direction away from the connector body 250 and defines an inlet having a peripheral rim 386.

  The receptacle portion 374 of the housing 370 includes a wall 390 that extends from one of the side walls 384 of the cavity defining portion 372 of the housing 370. The wall 390 defines a hollow plug storage chamber 392.

  Conductive prongs or blades 394 are embedded in a liquid tight relationship in the sidewall 384 during the molding process and extend into the chamber 378. The ends of the prongs 394 are exposed in the chamber 378 to contact a sensor such as sensor 292 or other device circuitry.

  A lug 395 is provided outside the wall 390. This is configured to cooperate with an insertable plug (not shown) associated with the sensor monitoring device and the data processing device. The lug 395 detachably holds the plug in the hollow plug storage chamber 392. Appropriate contacts in the plug contact the prong 394 to complete the circuit to the device 292.

  A cover 396 is removably positioned on the rim 386. Cover 396 is connected to rim 386 in a fluid tight relationship. Cover 396 is removable for mounting the sensing device within chamber 378 of housing 370.

  Cover 396 includes a port 397 that communicates the ambient atmosphere with the interior of the cavity or chamber 378. The port 397 is provided under the protective cap 398. This port or passage provides access to a reference source of ambient air. The sensor 292 can provide a comparison signal based on the difference between the condition sensed in the fluid system and the corresponding parameter in the ambient atmosphere. As described in connection with the embodiment of FIGS. 1-5, the port 397 is isolated from the port or passage 382 by the device 292 so that fluid tightness of the fluid system within the through hole 256 of the body 250 is achieved. Keep integrity.

  The sensing device 360 shown schematically in FIG. 16 can be inserted into the accessory housing 170 of the embodiment of FIGS. 1-6 or the accessory housing 370 of the embodiment of FIGS. This is located in the chamber 178 or 378 of the cavity defining portion 172 or 372. In order to ensure the fluid tightness of the fluid system incorporating the quick connector, the device 360 leaks into the chamber 178 or 378 with a suitable sealant or potting material as described above in connection with FIGS. Sealed in a stop relationship. Thus, there is no path between the port or passage 182 or 382 that communicates with the fluid system at the connector and the port 197 or 397 of the cover 196 or 396 that is exposed to the atmosphere.

  A sensor 360 shown in FIG. 16 is a variable capacitance pressure sensor. This includes a diaphragm 362 that receives fluid pressure in the through hole 56 or 256 via a passage 182 or 382. This diaphragm deforms according to the pressure in the system. A second stationary plate 363 is embedded in the dielectric material within the device 360. A lead 364 extends from the device to a suitable instrument. Diaphragm deflection results in a signal and / or voltage change in the capacitive characteristics of the device, which can then be sent to a meter and converted into a reading or input to the system monitor. If the second plate is exposed to the atmosphere, a differential pressure reading is provided.

  As in the above embodiment, the sensor 360 is disposed in a liquid tight relationship with the side wall 384 of the accessory chamber 378. The lead 364 may extend from the chamber through the opening defined by the rim 386 and may not require the use of a cover 396.

  Sensor 292 or sensor 360 is a vapor or liquid fuel pressure sensor. These may be differential pressure sensors or absolute pressure sensors. Such sensors include Delphi World and North American Headquarters (5725 Delphi Dr., Troy, MI 48098), Robert Bosch LLC (38000 Hills Tech Drive, Farmington Hills, MI 48331), or Sensata Technologies (529 Pleasant St , Attleboro, MA 02703). One such sensor is commonly known as an OBDII sensor and is useful in automotive fuel systems or steam systems.

  Non-powered or non-electrical devices can also be mounted in the cavities or chambers 178 or 378 of the accessory housing 170 or 370. Such devices can include mini accumulators or pulse dampers. It is also possible to install a bleed for high load applications such as a regulator having a third port for return flow when a fuel pressure regulator is not provided in the fuel tank, a recreational vehicle including a separate internal combustion engine for power generation, etc. Off-port, heater, etc. The connector body with the accessory housing can also include other devices such as tank drains, manual shut-off or diversion valves, and many other devices. All of these and many other options are available with the quick connector of the present invention.

  Referring now to FIGS. 13-15, a variation of the connector body 450 embodying the present invention is shown. As in the previous embodiment, this is a generally cylindrical elongated structure molded from a polymeric material such as nylon 12. This includes a wall 454 that defines a through-hole 456 that extends from a large diameter male member receiving end 458 to a barbed stem or hose connection end 460. The barbs cooperate in a known manner with the attached flexible hose to removably hold the flexible hose at the end 460.

  The stem end shown is suitable for attaching the flexible hose to the connector body 450. Many other end configurations are useful, depending on the components used in the fluid system, as in the previous embodiment. For example, the end 460 may or may not be configured to use an O-ring seal between the end 460 and the attached line when secured to an inflexible or rigid line. It can also be configured. The connection can be fixed in various ways by crimping, magnaforming, or the like.

  By changing the diameter of the inner bore 456, the bore is divided into a fluid passage portion 510, a tube end receptacle portion 501, and a seal storage portion 490. The fluid passage portion 510 communicates with the attached hose. Tube end receptacle portion 501 positions the end of the tube to be inserted. The seal housing portion 490 houses one or more O-ring seals and provides a fluid tight relationship with the inserted rigid tube.

  The body further defines a retainer housing section 470 adjacent to the male member receiving end 458. This includes an outer annular rim 472 and an inner annular rim 474 connected by a support member as in the previous embodiment. There is a generally “U” shaped retainer between the rims 472 and 474 that captures the expanded diameter of the tube so as not to dislodge and removably retains the male member within the connector body. Collaborate with male members in a known manner.

  In accordance with the present invention, the connector body 450 is provided with an accessory housing, generally indicated at 570, which is integrally formed with the connector body 450. This includes an accessory cavity defining portion 572. This is disposed substantially perpendicular to the longitudinal axis of the through-hole 456 defined by the cylindrical side wall 454 of the body 450.

  The cavity defining portion 572 defines an accessory chamber 578 that houses a sensor or other device as described in more detail below. The wall 454 of the connector body 450 includes a hole or passage 582 that communicates with the through hole 456. Thus, chamber 578 is in fluid communication with the fluid in the system including the quick connector coupling.

  A tubular side wall 584 defines an inlet extending from the connector body 450 and having a peripheral rim 586.

  A screw 587 that houses a sensor including a male screw is provided on the inner surface of the side wall 584. For example, the sensor 360 of FIG. The sensor is secured in the accessory chamber 578 by screws 587. Alternatively, the wall 584 may be externally threaded and the sensor may be provided with a flange or sleeve having internal threads.

  This embodiment eliminates the need for a cover, such as cover 196 or 396, and eliminates the need for the receptacle portion 174 or 374 of the accessory housing 170 or 370. The sensor in this configuration is fixed in fluid relation to the sidewall 584 to hold the sensor in the chamber 578 and provide access to system conditions within the chamber 578.

  Chamber 578 provides system status within accessory chamber 578 by communicating with fluid system within through-hole 456 via hole 582. A lead, such as lead 364, connects sensor 365 to the instrument, which converts the sensed signal to an appropriate reading or monitoring input.

  Various features of the present invention have been described with reference to the exemplary embodiments described above. It should be understood that various changes can be made without departing from the spirit and scope of the invention.

It is a partially broken perspective view of the quick connector main body which shows the principle of this invention. It is a top view of the quick connector main body of FIG. It is an end view of the quick connector main body of FIG. FIG. 4 is a partial cross-sectional view taken along line 4-4 of FIG. 2 of a quick connector having the connector body of FIGS. 1-3 with the sensing device mounted in the accessory chamber. FIG. 5 is a partial cross-sectional view of the quick connector having the connector body of FIGS. 1 to 3 along line 5-5 in FIG. 3 with the sensing device mounted in the accessory chamber. It is a perspective view of the quick connector main body of the slightly different form which shows the characteristic of this invention. It is a partially broken perspective view of the quick connector main body of FIG. It is a side view of the quick connector main body of FIG. It is an end view of the quick connector main body of FIG. It is a top view of the quick connector main body of FIG. FIG. 7 is a further perspective view of a different scale of the quick connector body of FIG. 6. 1 is a schematic view of a strain gauge sensor device that can be used in connection with the present invention. It is a perspective view of another quick connector main body which embodies the principle of the present invention. FIG. 14 is a cross-sectional view of the quick connector body of FIG. 14 taken along line 14-14 of FIG. FIG. 15 is a cross-sectional view of the quick connector body of FIG. 14 taken along line 15-15 of FIG. 1 is a schematic diagram of a variable capacitance sensing device useful in the present invention. FIG.

Claims (22)

A molded quick connector coupling body having a male member receiving end and a wall defining a through hole defining a fluid passageway,
A molded quick connector coupling body further comprising an integrally molded accessory housing having an accessory storage chamber defining portion.   The quick connector coupling body according to claim 1, wherein the accessory storage chamber defining portion includes a lower wall that defines a hole communicating with the through hole.   The quick connector coupling body of claim 2, wherein the cavity defining portion includes a side wall defining the accessory chamber. The sidewall includes a rim defining an opening leading to the accessory chamber;
The quick connector coupling body according to claim 3, wherein the accessory housing further includes a cover detachably connected to the rim in a liquid-tight relationship.   The quick connector coupling body according to claim 4, wherein the cover includes a port communicating with the outside of the accessory chamber.   The quick connector body according to claim 5, wherein the cover includes a protective cap overlying the port.   The quick connector body of claim 2, wherein the accessory housing further defines a receptacle portion.   8. The quick connector body of claim 7, wherein the receptacle portion includes a wall extending from one of the side walls of the accessory cavity defining portion to define a hollow plug storage chamber.   9. The accessory housing includes at least two conductive prongs with ends exposed in the accessory chamber and the hollow plug storage chamber on the side wall between the accessory chamber and the plug storage chamber. Quick connector body.   The quick connector body according to claim 1, wherein a sensor is disposed in the accessory chamber.   The quick connector main body according to any one of claims 3 to 9, wherein a sensor is disposed in the accessory chamber, and the sensor is fixed in a liquid-tight relationship with the side wall.   The quick connector body according to claim 11, wherein a liquid-tight sealant is disposed between the sensor and the side wall.   10. A quick connector body according to any one of claims 1 to 9, wherein the body is generally cylindrical and elongated, and the accessory housing is disposed substantially across the generally cylindrical elongated body.   10. The body according to any one of claims 1 to 9, wherein the body includes a stem portion opposite the male member receiving end, the stem portion being disposed at 90 degrees with respect to the rest of the body. The quick connector body described.   The quick connector body of claim 14, wherein the accessory housing is disposed substantially parallel to the stem portion. A quick connector assembly comprising a quick connector coupling body having a male member receiving end and a wall defining a through hole defining a fluid passageway, comprising:
The main body further includes an integrally formed accessory housing having an accessory storage chamber defining portion, and the accessory storage chamber defining portion includes a lower wall defining a hole communicating with the through hole;
A quick connector assembly, wherein a pressure sensing device is disposed in the accessory storage chamber.   The accessory storage chamber defining portion includes at least one sidewall defining the accessory storage chamber, and the pressure sensing device is disposed in the accessory chamber in a fluid tight relationship with the at least one sidewall. The quick connector assembly according to claim 16.   The quick connector assembly of claim 17, wherein the at least one sidewall is cylindrical, defines a rim, and includes an internally threaded portion.   19. A quick connector assembly according to any one of claims 16 to 18, wherein the pressure sensing device is an absolute pressure sensing device.   The quick connector assembly according to any one of claims 16 to 18, wherein the pressure sensing device is a differential pressure sensing device.   19. A quick connector assembly according to any one of claims 16 to 18, wherein the pressure sensing device is a strain gauge pressure sensing device.   19. A quick connector assembly according to any one of claims 16 to 18, wherein the pressure sensing device is a variable capacitance pressure sensing device.

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